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United States Patent |
5,618,115
|
Yates
|
April 8, 1997
|
Method of operating a rotating assembly
Abstract
A rotating assembly (10) comprises an inner (12) and an outer ring (14)
having a hydrostatic bearing therebetween. The bearing incorporates fluid
passageways (30 and 32) between confronting surfaces (22, 24, 26 and 28)
of the rings (12 and 14). When rotation is required the surfaces (22, 24,
26 and 28) are separated by the supply of a pressurised flow of fluid to
both of the passageways (30 and 32). The bearing can be locked to prevent
rotation by removal of the fluid in one of the passageways (32) whilst
maintaining the flow of pressurised fluid in the other passageway (30) so
as to hold confronting surfaces (26 and 28) in contact with one another.
Frictional forces between the confronting surfaces (26 and 28) prevents
rotation of the ring (14) and the flow of pressurised fluid prevents the
confronting surfaces (26 and 28) separating under the application of a
moment.
Inventors:
|
Yates; David E. (Evesham, GB2)
|
Assignee:
|
Rolls-Royce Power Engineering plc (Newcastle, GB2)
|
Appl. No.:
|
562622 |
Filed:
|
November 24, 1995 |
Foreign Application Priority Data
| Dec 22, 1994[GB] | 9425900 |
| Jul 19, 1995[GB] | 9514767 |
Current U.S. Class: |
384/110; 384/99 |
Intern'l Class: |
F16C 032/06 |
Field of Search: |
384/110,107,117,112,99,109
|
References Cited
U.S. Patent Documents
3575334 | Apr., 1971 | Stamm | 384/99.
|
3721480 | Mar., 1973 | Dee | 384/112.
|
4005916 | Feb., 1977 | Dillon | 384/117.
|
4884899 | Dec., 1989 | Schwartzman | 384/107.
|
Foreign Patent Documents |
1033802 | Jun., 1966 | GB.
| |
1213514 | Nov., 1970 | GB.
| |
1462048 | Jan., 1977 | GB.
| |
Primary Examiner: Footland; Lenard A.
Attorney, Agent or Firm: Oliff & Berridge
Claims
I claim:
1. A method of operating a rotating assembly comprising concentric inner
and outer annular members having an at least one hydrostatic bearing
therebetween, each bearing incorporating axially spaced apart passageways
between confronting bearing surfaces on the inner and outer members, the
bearing surfaces being capable of reacting axial loads, the method
comprising the steps of supplying a flow of pressurised fluid to the
passageways to separate the confronting surfaces of the inner and outer
members to permit relative rotation of the annular members and then
locking the bearing by removal of the flow of pressurised fluid from one
of the passageways whilst maintaining the flow of pressurised fluid to the
other passageway so as to hold at least one of the confronting surfaces on
the inner annular member in contact with at least one of the confronting
surfaces on the outer annular member, friction between the confronting
surfaces held in contact preventing rotational movement of the members,
the flow of pressurised fluid preventing separation of the surfaces in
contact under the application of a moment.
2. A method of operating a rotating assembly as claimed in claim 1 in which
the confronting surfaces on the inner and outer annular members are
conical.
3. A method of operating a rotating assembly as claimed in claim 1 in which
the pressurised fluid is provided to recesses in the confronting surface
of the inner annular member.
4. A method of operating a rotating assembly as claimed in claim 1 in which
restrictors are provided in the fluid supply to each passageway.
5. A method of operating a rotating assembly as claimed in claim 1 in which
the outer annular member rotates relative to the inner annular member and
is provided with teeth to facilitate rotation thereof.
6. A method of operating a rotating assembly as claimed in of claims 1-4 in
which the pressurised fluid is viscous to damp rotational movement of the
inner and outer annular members.
Description
The present invention relates to a method of operating a rotating assembly
and in particular to a method of operating a slewing ring intermittently.
Slewing rings are employed where slow accurately controlled rotation of
heavy equipment is required. Slewing rings comprise an inner and an outer
ring having a bearing therebetween to permit relative rotational movement
between the rings.
Slewing rings incorporating hydrostatic bearings are known. The advantage
of incorporating a hydrostatic bearing is that it offers a less expensive
construction as no hardened roller tracks are required as for bearings
which use rolling bearing elements.
In many applications the rotation of the slewing ring is intermittent. As
the static loads experienced by the slewing ring are often greater than
the dynamic loads it is advantageous to be able to lock the bearing
between intermittent movements. In slewing rings incorporating a
hydrostatic bearing this can be achieved by removal of the hydrostatic
pressure from the bearing permitting the bearing surfaces to contact. The
friction between the bearing surfaces opposes any rotational movement but
is not effective in reacting against an applied moment.
The present invention seeks to provide a method of operating a rotating
assembly incorporating a hydrostatic bearing which can be locked to oppose
both rotational movement and an applied moment.
According to the present invention a method of operating a rotating
assembly which comprises concentric inner and outer annular members having
an at least one hydrostatic bearing therebetween, each bearing
incorporates axially spaced apart passageways between confronting bearing
surfaces on the inner and outer members, the bearing surfaces being
capable of reacting axial loads, the method comprising the steps of
supplying a flow of pressurised fluid to the passageways to separate the
confronting surfaces of the inner and outer members to permit relative
rotation of the annular members and then locking the bearing by removal of
the flow of pressurised fluid from one of the passageways whilst
maintaining the flow of pressurised fluid to the other passageway so as to
hold at least one of the confronting surfaces on the inner annular member
in contact with at least one of the confronting faces on the outer annular
member, friction between the confronting faces held in contact preventing
rotational movement of the members, the flow of pressurised fluid
preventing separation of the surfaces in contact under the application of
a moment.
In the preferred embodiment of the present invention the confronting faces
on the inner and outer annular members are conical.
Preferably the pressurised fluid is provided to pockets in either the
confronting face of the inner annular member of the outer annular member.
Restrictors may be provided in the fluid supply to the pockets.
Either the inner or the outer annular member may be provided with teeth to
facilitate rotation thereof.
The present invention will now be described by way of example and with
reference to the accompanying drawing which is a cross-sectional view of a
slewing ring in accordance with the present invention.
Referring to the drawing a slewing ring, generally indicated at 10,
comprises an inner ring 12 and an outer ring 14 having a hydrostatic
bearing therebetween.
In operation the inner ring 12 is fixed to a static structure by fastening
means (not shown) which extend through apertures 13 provided therein. The
component to be rotated relative to the static structure is attached to
the outer ring 14 by fastening means (not shown) which extend through
apertures 15 provided therein. The outer ring 14 is provided with teeth 16
which cooperate with external means (not shown) to facilitate rotation of
the ring 14.
The hydrostatic bearing consists of two bearing surfaces 22 and 26 which
project from the inner surface 20 of the outer ring 14. The bearing
surfaces 22 and 26 confront bearing surfaces 24 and 28 provided in the
outer surface 21 of the inner ring 12. The bearing surfaces 22, 24, 26 and
28 are conical and a clearance is provided between them.
In operation when rotation is required the bearing surfaces 22, 24, 26 and
28 are separated by the supply of a pressurised flow of fluid, such as
oil. The oil is supplied to recesses 34 which define fluid passageways 30
and 32. The oil is supplied to the recesses 34 via ducts 36 and exhausts
through duct 38. The pressure of the oil in the recesses 34 causes the
bearing surfaces 22, 24, 26 and 28 to separate and acts as a lubricant to
permit rotation of the outer ring 14 relative to the inner annular ring
12.
Restrictors (not shown) in the fluid supply to each recess 34 causes the
pressure to drop as fluid leakage takes place. Thus the bearing surfaces
22, 24, 26 and 28 separate until the applied load balances the hydrostatic
pressure in each recess 34. The hydrostatic pressure in the fluid
passageways 30 and 32 react against one another to provide reaction
against an applied axial load.
Rotation of the outer ring 14 is intermittent. Once the outer ring 14 has
been rotated to the correct position the bearing is locked. Locking is
achieved by the removal of the hydrostatic pressure from the lower fluid
passageway 32 whilst pressure is maintained in the upper fluid passageway
30. The net hydrostatic pressure will provide a downward force which
pushes the bearing surfaces 26 and 28 into contact. The contact between
the bearing surfaces 26 and 28 provides static friction which opposes
rotational movement. The hydrostatic pressure prevents the surfaces 26 and
28 parting under the application of a moment.
It will be appreciated by one skilled in the art that the bearing could be
locked by removal of the hydrostatic pressure from the upper fluid
passageway 30 whilst pressure is maintained in the lower fluid passageway
32. The net hydrostatic pressure will provide a upwards force which pushes
the bearing surfaces 22 and 24 into contact. The contact between the
bearing surfaces 22 and 24 provides static friction which opposes
rotational movement and the hydrostatic pressure prevents the surfaces 22
and 24 parting under the application of a moment.
The assembly is reversible and each of the two rings can be either the
fixed or rotating part of the assembly, the rotating part being provided
with teeth allowing it to be rotated. Although the bearing surfaces shown
are conical they could be radial or of any other orientation provided they
can react axial loads.
One particular application of a slewing ring 10 in accordance with the
present invention is to support the nacelle of a horizontal axis wind
turbine. The slewing ring 10 rotates to align the turbine to the wind
direction.
The slewing ring 10 is subject to the dead weight of the nacelle and the
wind reaction forces. Due to the variability of the wind reaction forces
it is necessary to damp the slewing ring 10 to minimise movement and
consequent inertia forces.
The necessary damping is achieved by employing a highly viscous lubricant,
such as grease, between the inner ring 12 and the outer ring 14 of the
hydrostatic bearing.
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